US3257327A - Process for growing neodymium doped single crystal divalent metal ion tungstates - Google Patents
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- C—CHEMISTRY; METALLURGY
- C30—CRYSTAL GROWTH
- C30B—SINGLE-CRYSTAL GROWTH; UNIDIRECTIONAL SOLIDIFICATION OF EUTECTIC MATERIAL OR UNIDIRECTIONAL DEMIXING OF EUTECTOID MATERIAL; REFINING BY ZONE-MELTING OF MATERIAL; PRODUCTION OF A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; SINGLE CRYSTALS OR HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; AFTER-TREATMENT OF SINGLE CRYSTALS OR A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; APPARATUS THEREFOR
- C30B15/00—Single-crystal growth by pulling from a melt, e.g. Czochralski method
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- C—CHEMISTRY; METALLURGY
- C09—DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
- C09K—MATERIALS FOR MISCELLANEOUS APPLICATIONS, NOT PROVIDED FOR ELSEWHERE
- C09K11/00—Luminescent, e.g. electroluminescent, chemiluminescent materials
- C09K11/08—Luminescent, e.g. electroluminescent, chemiluminescent materials containing inorganic luminescent materials
- C09K11/77—Luminescent, e.g. electroluminescent, chemiluminescent materials containing inorganic luminescent materials containing rare earth metals
- C09K11/7708—Vanadates; Chromates; Molybdates; Tungstates
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- C—CHEMISTRY; METALLURGY
- C30—CRYSTAL GROWTH
- C30B—SINGLE-CRYSTAL GROWTH; UNIDIRECTIONAL SOLIDIFICATION OF EUTECTIC MATERIAL OR UNIDIRECTIONAL DEMIXING OF EUTECTOID MATERIAL; REFINING BY ZONE-MELTING OF MATERIAL; PRODUCTION OF A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; SINGLE CRYSTALS OR HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; AFTER-TREATMENT OF SINGLE CRYSTALS OR A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; APPARATUS THEREFOR
- C30B29/00—Single crystals or homogeneous polycrystalline material with defined structure characterised by the material or by their shape
- C30B29/10—Inorganic compounds or compositions
- C30B29/16—Oxides
- C30B29/22—Complex oxides
- C30B29/32—Titanates; Germanates; Molybdates; Tungstates
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01S—DEVICES USING THE PROCESS OF LIGHT AMPLIFICATION BY STIMULATED EMISSION OF RADIATION [LASER] TO AMPLIFY OR GENERATE LIGHT; DEVICES USING STIMULATED EMISSION OF ELECTROMAGNETIC RADIATION IN WAVE RANGES OTHER THAN OPTICAL
- H01S3/00—Lasers, i.e. devices using stimulated emission of electromagnetic radiation in the infrared, visible or ultraviolet wave range
- H01S3/14—Lasers, i.e. devices using stimulated emission of electromagnetic radiation in the infrared, visible or ultraviolet wave range characterised by the material used as the active medium
- H01S3/16—Solid materials
- H01S3/1601—Solid materials characterised by an active (lasing) ion
- H01S3/1603—Solid materials characterised by an active (lasing) ion rare earth
- H01S3/1611—Solid materials characterised by an active (lasing) ion rare earth neodymium
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01S—DEVICES USING THE PROCESS OF LIGHT AMPLIFICATION BY STIMULATED EMISSION OF RADIATION [LASER] TO AMPLIFY OR GENERATE LIGHT; DEVICES USING STIMULATED EMISSION OF ELECTROMAGNETIC RADIATION IN WAVE RANGES OTHER THAN OPTICAL
- H01S3/00—Lasers, i.e. devices using stimulated emission of electromagnetic radiation in the infrared, visible or ultraviolet wave range
- H01S3/14—Lasers, i.e. devices using stimulated emission of electromagnetic radiation in the infrared, visible or ultraviolet wave range characterised by the material used as the active medium
- H01S3/16—Solid materials
- H01S3/163—Solid materials characterised by a crystal matrix
- H01S3/1675—Solid materials characterised by a crystal matrix titanate, germanate, molybdate, tungstate
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S117/00—Single-crystal, oriented-crystal, and epitaxy growth processes; non-coating apparatus therefor
- Y10S117/918—Single-crystal waveguide
Definitions
- One of the more promising maser devices is that which utilizes .as the active material a diamagnetic crystal convice utilizing neodymium-containing calcium tungstate a divalent metal-ion tungstate containing various trivalent rare earth ions.
- the tungstate crystals are conveniently made by a method described as the CZochr-alski method. This method is described in an article by l. Czochralski in Zeitschrifit iii-r :Physikalische Chemie, volume 92, pages A recent description of the process is found in an article by K. Nassau and L. G. Van Uitert in Journal of Applied Physics, volume 31, page 1508 (1960).
- a melt is formed of a mixture of initial ingredients, the composition of the melt controlling the composition of the grown crystal.
- a seed crystal is inserted into the melt and simultaneously rotated and slowly withdrawn therefrom,
- melt must contain one atom percent neodymium, based on the calcium ions present, in order to grow a crystal containing only 0.24 atom percent neodymium.
- the absorption and emission spectra for trivalent rare earth ions in melt grown tungstates is not simple. from the present of a trivolent ion in a divalent lattice.
- Calcium tungstate doped with neodymium has a plurality of fluorescent lines in the 0.8 to 1.4 micron region.
- melt grown crystals An additional disadvantage of these melt grown crystals is the limited number of input signal frequencies capable of being amplified. For a minimum power input to produce maser action, each trivalent rare earth ion emits energy in only one primary line. Since the number of trivalent rare earth ions possessing the requisite characteristics necessary for maser operation is "limited, such ions being generally restricted to those having atomic numbers 58-60, 62, and 6471, the number of input signal (frequencies capable of being amplified is also limited.
- the divalent metal-ion tungstates of the invention are calcium tungstate, strontium tungstate and barium tungstate, each having a noncubic crystalline lattice structure of the Scheelite type. From about 0.01 atom percent to 15 atom percent of the divalent ions are replaced by trivalent rare earth ions asthe active maser material, the ions having atomic numbers 58-60, 62 and 64-71. Enhanced maser operation is dependent upon further incorporating in the crystal monovalent ions.
- the monovalent ions useful for enhancing maser operation are sodium, lithium and potassium;
- mixture of the desired divalent metal-ion tungstate or a divalent metal-ion compound that reacts with tungstic acid anhydride to form the tungstate, at least one trivalent rare-earth ion-containing substance having the desired rare-earth ions and at least one monovalent ioncontaining substance having the desired monovalent ions, is heated to a temperature suflicient to form a molten solution.
- a seed crystal is inserted into the melt and slowly withdrawn therefrom, crystal growth being thereby promoted on the seed crystal.
- the efficacy of the process is dependent upon the use of a critical amount of monovalent ion in the melt.
- the melt contains from 1.5 to 15 monovalent ions per trivalent ion in the melt with a maximum excess being attained when the melt contains 30 atom percent monovalent ion based on the number of divalent metal-ions present.
- Tungstate crystals grown by the method of the invention are found to be particularly suitable for maser use and to possess enhanced maser characteristics.
- the distribution coefficient of the trivalent rare earth ions in the melt compared to the ions incorporated into the crystal is greatly improved.
- the use of the critical amount of excess monovalent ion in the melt results, for calcium tungstate crystals doped with neodymium, in the incorporation in the crystal of 0.83 atom percent neodymium when the melt contains one atom percent neodymium.
- FIG. 1 on coordinates of relative emission intensity and Wavelength in microns is a plot showing the fluorescent line spectrum of a calcium tungstate crystal grown from a melt containing 8 atom percent sodium and 8 atom percent neodymium, the resulting crystal containing 2 atom percent neodymium.
- FIG. 2 on coordinates of relative emission intensity and wavelength in microns is a plot showing the fluorescent line spectrum of a calcium tungstate crystal grown from a melt containing 10 atom percent sodium and 2.5 atom percent neodymium, the resulting crystal containing 2 atom percent neodymium.
- FIG. 1 depicts the fluorescent line spectrum of a tungstate crystal grown from a melt containing one monovalent ion per trivalent rare earth ion. Crystals grown from melts containing no monovalent ion or less than one monovalent ion per trivalent rare earth ion exhibit similar spectra.
- FIG. 2 depicts the spectrum of tungstate crystals grown from a melt containing four monovalent ions per trivalent rare earth ion. Crystals grown from melts containing 1.5 to monovalent ions per trivalent rare earth ion exhibit similar spectra.
- Still another advantage accruing to the materials of the invention is an increase in intensity of the emitting lines.
- Such increase is illustrative by a comparison of the emission intensity of a second fluorescent line, line 4, exhibited by the sodium-containing tungstate of this invention of FIG. 2, with a second fluorescent line, line 2, of the usual sodium-containing tungstate of FIG. 1.
- the fluorescent line associated with the tungstate of the invention has a relative emission intensity of 60 percent of the most intense line
- the equivalent fluorescent line associated with the tungstate of FIG. 1 has a relative emission intensity of only 50 percent of the most intense line.
- a comparison of the figures shows that such increase is due to minimization of other fluorescent lines by the incorporated sodium ions in the amount indicated.
- a further advantage accruing to many materials of the invention is also illustrated by the preceding comparison of relative emission intensities.
- a first fluorescent line, line '3, at approximately 1.064 microns is observed under one joule of input power and a second fluorescent line, at approximately 1.065 microns, line 4, is observed under six joules of input power.
- the crystal of FIG. 1 requires three joules of power for the first line, at approximately 1.065 microns, line '1, and eighteen joule-s of power for the next line, at approximately 1.066 microns, line 2.
- the minimum power, or threshold, required to produce emission is significantly lower than that required for conventional crystals grown by the prior art technique.
- the divalent metal ion tungstate may be introduced into the initial mixture as either the tungstate per se or as a compound such as a divalent metal-ion salt, oxide, nitrate or carbonate that will react with tungstic acid anhydride to form the tungstate.
- a compound other than a tungstate it is preferable that the by-products of the reaction volatize during the subsequent heating step.
- the only critical requirement is that such by-product does not act as a contaminant during growth of the tungstate crystal.
- a stoichiometric amount of the divalent metal-ion compound and tungstic acid anhydride is utilized.
- deviations from the stoichiometry are permissible, such deviations being generally limited to an excess or deficiency of divalent metal ions in the order of 5 atom percent due to the tendency of second phase formation in the growing crystal for greater deviations.
- the trivalent rare earth ions and monovalent ions may also be introduced into the initial mixture in the form of compounds such as oxides, carbonates, salts or nitrates that, under the processing conditions, form a melt with the tungstate.
- the concentration of monovalent ions in the melt necessary to achieve the desired concentration in the crystal is critical. It has been determined that the melt must contain at least 1.5 monovalent ions
- Monovalent alkali ions suitable for practicing the invention are sodium, lithium and potassium.
- the use of rubidium and cesium ions are precluded in the method because of their large ionic radii which introduces strain into the tungstate crystalline lattice.
- the non rare-earth ion impurity limit is not critical.
- the amount of accidentally added trivalent rare-earth ion impurity should not exceed 0.1 the amount of the principal active trivalent rare-earth ion intentionally added.
- Ordinary reagent grade chemicals were used in the following specific examples and are suitable as the trivalent rare-earth ion impurity limits.
- the above initial reactants are heated to a temperature sufiicient to form a molten solution.
- This effect is readily determined visually.
- a typical initial mixture of calcium tungstate, 2.2 atom percent neodymium and 11 atom percent sodium requires a temperature of approximately 1550 C. to form a molten solution.
- the mixtures of the invention melt at temperatures in the order of 1525 C. to 1625 C.
- a crucible made of an inert material such as rhodium or iridium is used to hold the initial mixture and the resulting melt during processing.
- the atmosphere in which the heating is carried out is not critical. However, it is well known to use an inert or oxygen-containing atmosphere to prevent an ion in a higher valency state from being reduced to a lower valency state. For example, the tungsten ion, W+ is reduced to the lower valency state, W+ when a reducing atmosphere is used in conjunction with the elevated temperatures.
- a seed crystal is inserted into the melt and slowly withdrawn therefrom.
- the composition of the seed crystal- is not critical.
- the composition may range from undoped to heavily doped tungstate crystals.
- the seed crystal is generally slowly rotated while being withdrawn from the melt when uniformity of crystal growth is desired on all surfaces of the seed crystal.
- pulling rate of approximately one-half inch per hour and .a rotation rate of 60 r.p.m. are convenient in the obtaining of large crystals. Other pulling rates are equally feasible, however, although it has been found that the growing crystal has a tendency to crack when rates substantially in excess of four inches per hour are utilized.
- Example 1 100 grams CaWO 1.3 grams Nd O 2.7 grams W0 and 5.6 grams Na WO were initially mixed together. The mixture was then heated in a rhodium crucible in air to a temperature of 150 C. to form a molten solution. The solution contained 4 sodium ions per neodymium ion. A seed crystal of calcium tungstate was then inserted into the melt and simultaneously rotated and withdrawn from the melt. The rotation rate was approximately 60 rpm. and the pulling rate was approximately one-half inch per hour. The resulting calcium tungstate crystal contained approximately two atom percent neodymium.
- Example 2 100 grams CaWO 0.2 gram Ce (WO and 0.55 gram Li WO were initially mixed together. The mixture was then heated in an iridium crucible in air to a temperature of 1600 C. to form a molten solution. The solution contained 10 lithium ions per cerium ion. A seed crystal of calcium tungstate was then inserted into the melt and simultaneously rotated at rpm. and withdrawn from the melt at two inches per hour. The resulting calcium tungstate crystal contained approximately 0.1 atom percent cerium.
- Example 3 100 grams SrWO 2.1 grams NaTm(WO and 3.6 grams Na WO were initially mixed together. The mixture was then heated in a rhodium crucible in air to a temperature of 1580 C. to form a molten solution. The solution contained 5 sodium ions per thulium ion. A seed crystal of strontium tungstate'was then inserted into the melt and withdrawn therefrom at one-half inch per hour. The resulting strontium tungstate crystal contained approximately one atom percent thulium.
- a process for growing single crystals of calcium tungstate comprising forming a mixture of initial ingredients equivalent to CaWO together with a trivalent neodymium ion-containing substance containing from about 0.01 atom percent to 18 atom percent based on the total calcium ions present of neodymium ion and a monovalent sodium ion-containing substance containing from about 1.5 sodium ions to 15 sodium ions per neodymium ion present, up to a maximum of 30 atom percent based on the total calcium ions present, heating said initial ingredients to a temperature sufiicien-t to form a molten solution, inserting a seed crystal into said molten solution and slowly withdrawing said seed crystal from said solution, thereby promoting crystal growth on said seed crystal.
- neodymium-containing substance contains from about 0.1 to 4.0 atom percent of neodymium.
- Nassau et a1. Preparation of Large Calcium-Tungstate Crystals Containing Paramagnetic Ions for Maser Applications, J. App. Phys, vol. 31, #8, August 1960, page 1508.
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Description
June 21, 1966 K. NASSAU 3, 57,3 7
PROCESS FOR GROWING NEODYMIUM DOPED SINGLE CRYSTAL DIVALENT METAL ION TUNGSTATES Filed May 7. 1962 RELATIVE EMISSION INTENSITY I400- I: \3 (T) |2OO 2 2 If ZIOOO- Z /'4 9 e00 U) Q E 600- uJ LL] 400- E m 200- at I I I.O4I6 I.O526 mess I .0752 I.O869 |.o9e9 WAVELENGTH IN MICRONS INI/ENTOR k. NASSAU BY A T TORNE I United States Patent ice 3,257,327 PROCESS FOR GROWING NEODYMIUM DOPED SINGLE CRYSTAL DIVALENT METAL ION TUNGSTATES Kurt Nassau, Springfield, N.J., assignor to Bell Telephone Laboratories, Incorporated, New York, N.Y., a corporation of New York Filed. May 7,1962, Ser. No. 192,723 3 Claims. (Cl. 252-3015) This invention relates to a method of growing single crystal tungstates containing small additions of monovalent and paramagnetic ions. and to crystalsso grown.
In recent years there have been developed two classes of solid state maser devices, the microwave maser and the optical maser, in which electromagnetic wave energy amplification by stim ulated emission of radiation occurs. The mechanics of microwave amplification are well detailed in the literature as, for example, in the article entitled A Maser, page 18 of the Microwave Journal for November/December 1958, and the article-entitled A Solid-State Maser, a Supercooled Amplifier, page 16, Electronics, Engineering Edition, April 25, 1958. Devices inwhich the stimulated frequency is in the spectral range from far infrared to ultraviolet, encompassing the wavelength range of from 100 A. to 2 10 A., are termed optical masers and are directly analogous in operation to the microwave maser. One particular description of devices of this type is found in United States Patent 2,929,922 to Schawlow and Townes.
One of the more promising maser devices is that which utilizes .as the active material a diamagnetic crystal convice utilizing neodymium-containing calcium tungstate a divalent metal-ion tungstate containing various trivalent rare earth ions.
The tungstate crystals are conveniently made by a method described as the CZochr-alski method. This method is described in an article by l. Czochralski in Zeitschrifit iii-r :Physikalische Chemie, volume 92, pages A recent description of the process is found in an article by K. Nassau and L. G. Van Uitert in Journal of Applied Physics, volume 31, page 1508 (1960). In accordance with this method, a melt is formed of a mixture of initial ingredients, the composition of the melt controlling the composition of the grown crystal. A seed crystal is inserted into the melt and simultaneously rotated and slowly withdrawn therefrom,
m-ateiral, calcium tungstate doped with nedoymium, the
melt must contain one atom percent neodymium, based on the calcium ions present, in order to grow a crystal containing only 0.24 atom percent neodymium.
Further, as understood by the art, the absorption and emission spectra for trivalent rare earth ions in melt grown tungstates is not simple. from the present of a trivolent ion in a divalent lattice.
Part of the complexity arises I 3,257,327 Patented June 21, 1966 The particular spectrum characteristic of the trivalent ion is dependent on the particular environment in which the ion is located in the tungstate crystalline lattice. Various permissible locations are available for the ion during crystal growth including one adjacent a divalent metal-ion vacancy, one adjacent another trivalent ion, one adjacent both a vacancy and another trivalet ion or one completely surrounded by divalent metal ions. Each particular ordering around the rare earth ion gives rise to a distinct series of absorption and emission lines. The resulting multiplicity of such lines dissipates power and detracts from the intensity of any one of them. Oalcium tungstate doped with cerium, for example, has a plurality of paramagnetic resonance lines in the region g=1.43 to g=2.92. Calcium tungstate doped with neodymium has a plurality of fluorescent lines in the 0.8 to 1.4 micron region.
An additional disadvantage of these melt grown crystals is the limited number of input signal frequencies capable of being amplified. For a minimum power input to produce maser action, each trivalent rare earth ion emits energy in only one primary line. Since the number of trivalent rare earth ions possessing the requisite characteristics necessary for maser operation is "limited, such ions being generally restricted to those having atomic numbers 58-60, 62, and 6471, the number of input signal (frequencies capable of being amplified is also limited.
In accordance with the invention, it has been discovered that certain divalent metal-ion containing tungstate compositions ofm atter exhibit enhanced maser characteristics.
when 'grown by the methods of the invention. The divalent metal-ion tungstates of the invention are calcium tungstate, strontium tungstate and barium tungstate, each having a noncubic crystalline lattice structure of the Scheelite type. From about 0.01 atom percent to 15 atom percent of the divalent ions are replaced by trivalent rare earth ions asthe active maser material, the ions having atomic numbers 58-60, 62 and 64-71. Enhanced maser operation is dependent upon further incorporating in the crystal monovalent ions. The monovalent ions useful for enhancing maser operation are sodium, lithium and potassium;
In accordance with the method of the invention, a
. mixture of the desired divalent metal-ion tungstate or a divalent metal-ion compound that reacts with tungstic acid anhydride to form the tungstate, at least one trivalent rare-earth ion-containing substance having the desired rare-earth ions and at least one monovalent ioncontaining substance having the desired monovalent ions, is heated to a temperature suflicient to form a molten solution. A seed crystal is inserted into the melt and slowly withdrawn therefrom, crystal growth being thereby promoted on the seed crystal. V
It has been determined that the efficacy of the process is dependent upon the use of a critical amount of monovalent ion in the melt. In particular, the melt contains from 1.5 to 15 monovalent ions per trivalent ion in the melt with a maximum excess being attained when the melt contains 30 atom percent monovalent ion based on the number of divalent metal-ions present.
Tungstate crystals grown by the method of the invention are found to be particularly suitable for maser use and to possess enhanced maser characteristics. In particular, it is found that the distribution coefficient of the trivalent rare earth ions in the melt compared to the ions incorporated into the crystal is greatly improved. The use of the critical amount of excess monovalent ion in the melt results, for calcium tungstate crystals doped with neodymium, in the incorporation in the crystal of 0.83 atom percent neodymium when the melt contains one atom percent neodymium. As previously noted, the prior art technique results in the incorporation of only 0.24 atom percent neodymium from a melt containing one atom percent of the ion.- It has been found that the distribution coefficient of all trivalent ion materials of the invention is improved by the critical monovalent ion inclusions.
Further advantages accruing to crystals grown by the instant method may be more easily understood by reference to the drawing in which:
FIG. 1 on coordinates of relative emission intensity and Wavelength in microns is a plot showing the fluorescent line spectrum of a calcium tungstate crystal grown from a melt containing 8 atom percent sodium and 8 atom percent neodymium, the resulting crystal containing 2 atom percent neodymium.
FIG. 2 on coordinates of relative emission intensity and wavelength in microns is a plot showing the fluorescent line spectrum of a calcium tungstate crystal grown from a melt containing 10 atom percent sodium and 2.5 atom percent neodymium, the resulting crystal containing 2 atom percent neodymium.
Referring more particularly to FIGS. 1 and 2, FIG. 1 depicts the fluorescent line spectrum of a tungstate crystal grown from a melt containing one monovalent ion per trivalent rare earth ion. Crystals grown from melts containing no monovalent ion or less than one monovalent ion per trivalent rare earth ion exhibit similar spectra. FIG. 2 depicts the spectrum of tungstate crystals grown from a melt containing four monovalent ions per trivalent rare earth ion. Crystals grown from melts containing 1.5 to monovalent ions per trivalent rare earth ion exhibit similar spectra.
From a comparison of the figures, it is seen that critical inclusions in the melt result in a sodium shift of the primary fluorescent line from 1.066 microns, line 1, to 1.065 microns, line 3. This shift is illustrative of a further advantage accruing to the crystals of the invention; namely, by the critical monovalent ion additions to the melt, the primary emitting lines can be varied. The number of input signal frequencies capable of being amplified is accordingly increased by such mono-valent ion inclusions.
Still another advantage accruing to the materials of the invention is an increase in intensity of the emitting lines. Such increase is illustrative by a comparison of the emission intensity of a second fluorescent line, line 4, exhibited by the sodium-containing tungstate of this invention of FIG. 2, with a second fluorescent line, line 2, of the usual sodium-containing tungstate of FIG. 1. Whereas the fluorescent line associated with the tungstate of the invention has a relative emission intensity of 60 percent of the most intense line, the equivalent fluorescent line associated with the tungstate of FIG. 1 has a relative emission intensity of only 50 percent of the most intense line. A comparison of the figures shows that such increase is due to minimization of other fluorescent lines by the incorporated sodium ions in the amount indicated.
A further advantage accruing to many materials of the invention is also illustrated by the preceding comparison of relative emission intensities. For the crystal of FIG. 2, a first fluorescent line, line '3, at approximately 1.064 microns, is observed under one joule of input power and a second fluorescent line, at approximately 1.065 microns, line 4, is observed under six joules of input power. In contrast, the crystal of FIG. 1 requires three joules of power for the first line, at approximately 1.065 microns, line '1, and eighteen joule-s of power for the next line, at approximately 1.066 microns, line 2. For many crystals of the invention, therefore, the minimum power, or threshold, required to produce emission is significantly lower than that required for conventional crystals grown by the prior art technique.
To obtain the lines of FIGS. 1 and 2, measurements were made with a Perkin Elmer grating spectrometer. Emission was excited by illuminating the sample with a mercury lamp and detecting the fluorescent light by means of a lead sulfide detector calibrated in arbitrary units of 0 to 1400.
The divalent metal ion tungstate may be introduced into the initial mixture as either the tungstate per se or as a compound such as a divalent metal-ion salt, oxide, nitrate or carbonate that will react with tungstic acid anhydride to form the tungstate. When a compound other than a tungstate is utilized, it is preferable that the by-products of the reaction volatize during the subsequent heating step. However, the only critical requirement is that such by-product does not act as a contaminant during growth of the tungstate crystal.
Typically, a stoichiometric amount of the divalent metal-ion compound and tungstic acid anhydride is utilized. However, deviations from the stoichiometry are permissible, such deviations being generally limited to an excess or deficiency of divalent metal ions in the order of 5 atom percent due to the tendency of second phase formation in the growing crystal for greater deviations.
The trivalent rare earth ions and monovalent ions may also be introduced into the initial mixture in the form of compounds such as oxides, carbonates, salts or nitrates that, under the processing conditions, form a melt with the tungstate.
As understood by the art, although in principle there is no lower limit on the concentration of trivalent rareearth ion in the formed crystal, a practical limit of about 0.01 atom percent rare earth ion in place of the divalent meta-l ion of the tungstate host lattice is imposed by the necessity of having suflicient unpaired electrons available in the negative temperature state to adequately amplify the output signal. The preferred concentrations are in the order of 0.1 atom percent to four atom percent with maximum concentration being in the order of 15 atom percent. Concentrations above fifteen atom percent are considered undesirable due to difliculties encountered in forming strain-free crystals and line broadening effects associated with such concentrations which detract from the magnitude of amplification of the input signal.
Although not so limited, in accordance with a preferred embodiment herein, it is considered desirable to utilize an excess of twenty percent trivalent ion in the melt to compensate for the prior discussed distribution coeflicient, thereby ensuring that the desired number of trivalent ions are incorporated into the grown crystal. A maximum trivalent ion concentration in the melt is therefore eighteen atom percent. In contrast, the distribution coeflicient of the prior art technique dictates an excess of 317 percent trivalent ion in the melt.
The concentration of monovalent ions in the melt necessary to achieve the desired concentration in the crystal is critical. It has been determined that the melt must contain at least 1.5 monovalent ions |per trivalent ion in order to produce the previously discussed improvements in tungstate crystals. It has been determined, for example, that the use of one monovalent ion per trivalent ion in the melt, results in crystals in which the distribution coeflicient is not appreciably enhanced over monovalent ion-free crystals. Desirably, the melt contains monovalent ion additions up to 15 monovalent ions per trivalent ion. A maximum concentration in the melt of 30 atom percent results, however, due to difliculty in growing strain-free crystals. A preferred range of monovalent ion inclusions in the melt is from 3 to 10 monovalent ions per trivalent rare earth ion in the melt.
Monovalent alkali ions suitable for practicing the invention are sodium, lithium and potassium. The use of rubidium and cesium ions are precluded in the method because of their large ionic radii which introduces strain into the tungstate crystalline lattice.
There are no critical limits to particle sizes of the initial reactants since a molten solution is formed of the initial mixture. Generally, the non rare-earth ion impurity limit is not critical. Preferably the amount of accidentally added trivalent rare-earth ion impurity should not exceed 0.1 the amount of the principal active trivalent rare-earth ion intentionally added. Ordinary reagent grade chemicals were used in the following specific examples and are suitable as the trivalent rare-earth ion impurity limits.
The above initial reactants are heated to a temperature sufiicient to form a molten solution. This effect is readily determined visually. A typical initial mixture of calcium tungstate, 2.2 atom percent neodymium and 11 atom percent sodium requires a temperature of approximately 1550 C. to form a molten solution. In general, the mixtures of the invention melt at temperatures in the order of 1525 C. to 1625 C. To minimize contamination, a crucible made of an inert material such as rhodium or iridium is used to hold the initial mixture and the resulting melt during processing.
The atmosphere in which the heating is carried out is not critical. However, it is well known to use an inert or oxygen-containing atmosphere to prevent an ion in a higher valency state from being reduced to a lower valency state. For example, the tungsten ion, W+ is reduced to the lower valency state, W+ when a reducing atmosphere is used in conjunction with the elevated temperatures.
After sufficient heating to form a melt of the initial mixture, a seed crystal is inserted into the melt and slowly withdrawn therefrom. The composition of the seed crystal-is not critical. The composition may range from undoped to heavily doped tungstate crystals. Although not necessary, the seed crystal is generally slowly rotated while being withdrawn from the melt when uniformity of crystal growth is desired on all surfaces of the seed crystal. A |pulling rate of approximately one-half inch per hour and .a rotation rate of 60 r.p.m. are convenient in the obtaining of large crystals. Other pulling rates are equally feasible, however, although it has been found that the growing crystal has a tendency to crack when rates substantially in excess of four inches per hour are utilized.
Specific examples of tungstate crystals grown by the method of the invention are given below. These examples are to be construed as illustrative only and not as limiting in any way the scope and spirit of the invention.
Example 1 100 grams CaWO 1.3 grams Nd O 2.7 grams W0 and 5.6 grams Na WO were initially mixed together. The mixture was then heated in a rhodium crucible in air to a temperature of 150 C. to form a molten solution. The solution contained 4 sodium ions per neodymium ion. A seed crystal of calcium tungstate was then inserted into the melt and simultaneously rotated and withdrawn from the melt. The rotation rate was approximately 60 rpm. and the pulling rate was approximately one-half inch per hour. The resulting calcium tungstate crystal contained approximately two atom percent neodymium.
Example 2 100 grams CaWO 0.2 gram Ce (WO and 0.55 gram Li WO were initially mixed together. The mixture was then heated in an iridium crucible in air to a temperature of 1600 C. to form a molten solution. The solution contained 10 lithium ions per cerium ion. A seed crystal of calcium tungstate was then inserted into the melt and simultaneously rotated at rpm. and withdrawn from the melt at two inches per hour. The resulting calcium tungstate crystal contained approximately 0.1 atom percent cerium.
. Example 3 100 grams SrWO 2.1 grams NaTm(WO and 3.6 grams Na WO were initially mixed together. The mixture was then heated in a rhodium crucible in air to a temperature of 1580 C. to form a molten solution. The solution contained 5 sodium ions per thulium ion. A seed crystal of strontium tungstate'was then inserted into the melt and withdrawn therefrom at one-half inch per hour. The resulting strontium tungstate crystal contained approximately one atom percent thulium.
What is claimed is:
1. A process for growing single crystals of calcium tungstate comprising forming a mixture of initial ingredients equivalent to CaWO together with a trivalent neodymium ion-containing substance containing from about 0.01 atom percent to 18 atom percent based on the total calcium ions present of neodymium ion and a monovalent sodium ion-containing substance containing from about 1.5 sodium ions to 15 sodium ions per neodymium ion present, up to a maximum of 30 atom percent based on the total calcium ions present, heating said initial ingredients to a temperature sufiicien-t to form a molten solution, inserting a seed crystal into said molten solution and slowly withdrawing said seed crystal from said solution, thereby promoting crystal growth on said seed crystal.
2. A process in accordance with claim 1 wherein said neodymium-containing substance contains from about 0.1 to 4.0 atom percent of neodymium.
3. A process in accordance with claim 2 wherein the said sodium-containing substances contains from about 3 to 10 sodium ions per neodymium ion.
References Cited by the Examiner UNITED STATES PATENTS 2,954,300 9/ 1960 Tr-iebwasser. 3,003,112 10/ 1961 Van Uitert 23301 X 3,053,635 9/1962 Shockley 23-30l X OTHER REFERENCES Kroger: Some Aspects of the Luminescence of Solids, Elsevier Pub. Co., New York, 1948, pages 290-298.
Nassau et a1.: Preparation of Large Calcium-Tungstate Crystals Containing Paramagnetic Ions for Maser Applications, J. App. Phys, vol. 31, #8, August 1960, page 1508.
TOBIAS E. LEVOW, Primary Examiner. MAURICE A. BRINDISI, Examiner. R. D. EDMONDS, Assistant Examiner.
Claims (1)
1. A PROCESS FOR GROWING SINGLE CRYSTALS OF CALCIUM TUNGSTATE COMPRISING FORMING A MIXTUE OF INITIAL INGREDIENTS EQUIVALENT TO CAWO4 TOGETHER WITH A TRIVALENT NEODYMIUM ION-CONTAINING SUBSTANCE CONTAINING FROM ABOUT 0.01 ATOM PERCENT TO 18 ATOM PERCENT BASED ON THE TOTAL CALCIUM IONS PRESENT OF NEODYMIUM ION AND A MONOVALENT SODIUM ION-CONTAINING SUBSTANCE CONTAINING FROM ABOUT 1.5 SODIUM IONS TO 15 SODIUM IONS PER NEODYMIUM ION PRESENT, UP TO A MIXIMUM OF 30 ATOM PERCENT BASED ON THE TOTAL CALCIUM IONS PRESENT, HEATING SAID INITIAL INGREDIENTS TO A TEMPERATURE SUFFICIENT TO FORM A MOLTEN SOLUTION, INSERTING A SEED CRYSTAL INTO SAID MOLTEN SOLUTION AND SLOWLY WITHDRAWING SAID SEED CRYSTAL FROM SAID SOLUTION, THEREBY PROMOTING CRYSTAL GROWTH ON SAID SEED CRYSTAL.
Priority Applications (6)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
BE631924D BE631924A (en) | 1962-05-07 | ||
NL292372D NL292372A (en) | 1962-05-07 | ||
US192723A US3257327A (en) | 1962-05-07 | 1962-05-07 | Process for growing neodymium doped single crystal divalent metal ion tungstates |
DEW34381A DE1276012B (en) | 1962-05-07 | 1963-04-29 | Process for growing single crystals doped with paramagnetic ions from tungstates of the alkaline earth metals calcium, strontium or barium |
GB17308/63A GB1033975A (en) | 1962-05-07 | 1963-05-02 | Improvements in or relating to the growth of single crystals of divalent metal ion tungstates |
FR934024A FR1356173A (en) | 1962-05-07 | 1963-05-07 | Monocrystalline tungstate growth process |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US192723A US3257327A (en) | 1962-05-07 | 1962-05-07 | Process for growing neodymium doped single crystal divalent metal ion tungstates |
Publications (1)
Publication Number | Publication Date |
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US3257327A true US3257327A (en) | 1966-06-21 |
Family
ID=22710802
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US192723A Expired - Lifetime US3257327A (en) | 1962-05-07 | 1962-05-07 | Process for growing neodymium doped single crystal divalent metal ion tungstates |
Country Status (5)
Country | Link |
---|---|
US (1) | US3257327A (en) |
BE (1) | BE631924A (en) |
DE (1) | DE1276012B (en) |
GB (1) | GB1033975A (en) |
NL (1) | NL292372A (en) |
Cited By (9)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3374444A (en) * | 1964-10-21 | 1968-03-19 | Du Pont | Vacancy compensated calcium neodymium vanadate phosphors |
US3375464A (en) * | 1964-05-14 | 1968-03-26 | Du Pont | Single-phase, solid solution luminescent compositions, preparation thereof and lasers containing same |
US3420780A (en) * | 1962-08-10 | 1969-01-07 | Comp Generale Electricite | Process for removing the colour from oriented monocrystals |
US3427566A (en) * | 1964-03-02 | 1969-02-11 | Union Carbide Corp | Solid state laser device using gadolinium oxide as the host material |
US3459667A (en) * | 1964-02-26 | 1969-08-05 | Rca Corp | Phosphor and method of preparation thereof |
US3488292A (en) * | 1967-02-16 | 1970-01-06 | Westinghouse Electric Corp | Alkaline-earth metal pyrophosphate phosphors |
US3502590A (en) * | 1967-03-01 | 1970-03-24 | Rca Corp | Process for preparing phosphor |
US3515675A (en) * | 1966-12-27 | 1970-06-02 | Lockheed Aircraft Corp | Method for making luminescent materials |
EP2727975A1 (en) * | 2011-06-28 | 2014-05-07 | Ocean's King Lighting Science & Technology Co., Ltd. | Cerium doped magnesium barium tungstate luminescent thin film, manufacturing method and application thereof |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2954300A (en) * | 1958-10-31 | 1960-09-27 | Ibm | Method of preparation of single crystal ferroelectrics |
US3003112A (en) * | 1959-05-25 | 1961-10-03 | Bell Telephone Labor Inc | Process for growing and apparatus for utilizing paramagnetic crystals |
US3053635A (en) * | 1960-09-26 | 1962-09-11 | Clevite Corp | Method of growing silicon carbide crystals |
-
0
- BE BE631924D patent/BE631924A/xx unknown
- NL NL292372D patent/NL292372A/xx unknown
-
1962
- 1962-05-07 US US192723A patent/US3257327A/en not_active Expired - Lifetime
-
1963
- 1963-04-29 DE DEW34381A patent/DE1276012B/en active Pending
- 1963-05-02 GB GB17308/63A patent/GB1033975A/en not_active Expired
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2954300A (en) * | 1958-10-31 | 1960-09-27 | Ibm | Method of preparation of single crystal ferroelectrics |
US3003112A (en) * | 1959-05-25 | 1961-10-03 | Bell Telephone Labor Inc | Process for growing and apparatus for utilizing paramagnetic crystals |
US3053635A (en) * | 1960-09-26 | 1962-09-11 | Clevite Corp | Method of growing silicon carbide crystals |
Cited By (11)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3420780A (en) * | 1962-08-10 | 1969-01-07 | Comp Generale Electricite | Process for removing the colour from oriented monocrystals |
US3459667A (en) * | 1964-02-26 | 1969-08-05 | Rca Corp | Phosphor and method of preparation thereof |
US3427566A (en) * | 1964-03-02 | 1969-02-11 | Union Carbide Corp | Solid state laser device using gadolinium oxide as the host material |
US3375464A (en) * | 1964-05-14 | 1968-03-26 | Du Pont | Single-phase, solid solution luminescent compositions, preparation thereof and lasers containing same |
US3374444A (en) * | 1964-10-21 | 1968-03-19 | Du Pont | Vacancy compensated calcium neodymium vanadate phosphors |
US3515675A (en) * | 1966-12-27 | 1970-06-02 | Lockheed Aircraft Corp | Method for making luminescent materials |
US3488292A (en) * | 1967-02-16 | 1970-01-06 | Westinghouse Electric Corp | Alkaline-earth metal pyrophosphate phosphors |
US3502590A (en) * | 1967-03-01 | 1970-03-24 | Rca Corp | Process for preparing phosphor |
EP2727975A1 (en) * | 2011-06-28 | 2014-05-07 | Ocean's King Lighting Science & Technology Co., Ltd. | Cerium doped magnesium barium tungstate luminescent thin film, manufacturing method and application thereof |
EP2727975A4 (en) * | 2011-06-28 | 2014-12-31 | Oceans King Lighting Science | Cerium doped magnesium barium tungstate luminescent thin film, manufacturing method and application thereof |
US9270084B2 (en) | 2011-06-28 | 2016-02-23 | Ocean's King Lighting Science & Technology Co., Ltd. | Cerium doped magnesium barium tungstate luminescent thin film, manufacturing method and application thereof |
Also Published As
Publication number | Publication date |
---|---|
NL292372A (en) | 1900-01-01 |
GB1033975A (en) | 1966-06-22 |
BE631924A (en) | 1900-01-01 |
DE1276012B (en) | 1968-08-29 |
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